A buffer station for thermal control of semiconductor substrates in a semiconductor substrate processing system is configured to interface with first and second vacuum transfer modules of the system so as to allow substrates to be transferred therebetween. The buffer station comprises a first vacuum transfer module interface configured to allow substrates to be transferred between the first vacuum transfer module and the buffer station, and a second transfer module interface configured to allow substrates to be transferred between the second vacuum transfer module and the buffer station. At least one buffer chamber between the first and second vacuum transfer module interfaces includes a lower pedestal configured to receive a substrate on a support surface thereof. One or more semiconductor substrate storage shelves are above the lower pedestal. Each shelf is configured to receive a substrate from the first or second vacuum transfer module and store the respective substrate thereon.
Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A buffer station for thermal control of semiconductor substrates in a modular semiconductor substrate processing system being transferred therethrough, the buffer station configured to interface with first and second vacuum transfer modules of the modular semiconductor substrate processing system so as to allow semiconductor substrates to be transferred therebetween, the buffer station comprising: a first vacuum transfer module interface configured to allow one or more semiconductor substrates to be transferred between the first vacuum transfer module and the buffer station at vacuum pressure; a second vacuum transfer module interface configured to allow one or more semiconductor substrates to be transferred between the second vacuum transfer module and the buffer station at vacuum pressure; and at least one buffer chamber between the first vacuum transfer module interface and the second vacuum transfer module interface, each of the at least one buffer chambers including a lower pedestal that forms a bottom most interior surface of the buffer chamber, that is configured to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module on a support surface thereof, and that is operable to perform a heating or cooling operation on the semiconductor substrate received thereon, and one or more semiconductor substrate storage shelves that are located above the lower pedestal, that extend outwardly from a side wall of the buffer chamber, and that are each configured to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module wherein each semiconductor substrate storage shelf is operable to store a respective semiconductor substrate thereon.
A buffer station in a semiconductor processing system allows semiconductor wafers to be transferred between two vacuum transfer modules. The station includes two vacuum interfaces for transferring wafers to/from the modules. A buffer chamber between the interfaces has a lower pedestal to hold a wafer, with heating/cooling capability to thermally control the wafer. One or more storage shelves are located above the pedestal to store wafers temporarily. This enables wafers to be staged, and their temperatures controlled, between processing steps performed by modules connected to the vacuum transfer modules.
2. The buffer station of claim 1 , wherein the lower pedestal includes a heater layer which includes independently controllable heater zones operable to independently control and tune the spatial and temporal temperature of the support surface of the lower pedestal; and/or the lower pedestal includes a cooling layer operable to reduce the temperature of the lower pedestal.
The buffer station's lower pedestal, as described in the previous buffer station description, includes a heater layer with independently controllable heater zones, allowing precise spatial and temporal temperature control of the wafer support surface. Alternatively, or in addition, the lower pedestal includes a cooling layer to reduce the pedestal's temperature, enabling cooling of the wafer.
3. The buffer station of claim 1 , wherein the at least one buffer chamber includes a heat shield between the lower pedestal and the one or more semiconductor substrate storage shelves wherein the heat shield is operable to reduce heat transfer between a semiconductor substrate supported on the lower pedestal and one or more substrates supported on the respective one or more semiconductor substrate storage shelves during processing.
The buffer station's buffer chamber, as described in the previous buffer station description, includes a heat shield positioned between the lower pedestal and the storage shelves. This heat shield reduces heat transfer between a wafer on the pedestal (being heated or cooled) and wafers stored on the shelves, preventing unwanted temperature changes to the stored wafers during processing.
4. The buffer station of claim 1 , wherein: (a) the at least one buffer chamber includes a first buffer chamber disposed above a second buffer chamber wherein the first buffer chamber is configured to allow semiconductor substrates to be transferred from the first vacuum transfer module to the second vacuum transfer module and the second buffer chamber is configured to allow semiconductor substrates to be transferred from the second vacuum transfer module to the first vacuum transfer module; or (b) the at least one buffer chamber includes a first buffer chamber disposed above a second buffer chamber wherein the first buffer chamber is configured to allow semiconductor substrates to be transferred from the first vacuum transfer module to the second vacuum transfer module and the second buffer chamber is configured to allow semiconductor substrates to be transferred from the second vacuum transfer module to the first vacuum transfer module wherein the buffer station includes a driver operable to lower the first and second buffer chambers so as to allow semiconductor substrates to be transferred through the first buffer chamber and to raise the first and second buffer chambers so as to allow semiconductor substrates to be transferred through the second buffer chamber.
The buffer station, as described in the previous buffer station description, can have multiple buffer chambers arranged vertically. In one configuration, a first buffer chamber is positioned above a second. The first chamber facilitates wafer transfer from the first vacuum transfer module to the second, and the second chamber allows transfer from the second vacuum transfer module back to the first. Alternatively, the buffer station uses a driver to lower/raise the buffer chambers so that wafer can be transferred back and forth.
5. The buffer station of claim 1 , wherein: (a) the buffer station is configured to be in fluid communication with an inert gas supply, the inert gas supply operable to supply inert gas to the at least one buffer chamber so as to facilitate heat transfer between the lower pedestal and a semiconductor substrate supported on the lower pedestal; (b) the buffer station is configured to be in fluid communication with a vacuum pump, the vacuum pump operable to control the pressure within the at least one buffer chamber; (c) the first vacuum transfer module interface includes a first slit valve operable to seal a first port of the first vacuum transfer module interface, the first slit valve configured to isolate the environment of the at least one buffer chamber from a vacuum environment of the first vacuum transfer module; (d) the second vacuum transfer module interface includes a second slit valve operable to seal a first port of the second vacuum transfer module interface, the second slit valve configured to isolate the environment of the at least one buffer chamber from a vacuum environment of the second vacuum transfer module; (e) the buffer station includes alignment pins configured to align a first port of the first vacuum transfer module interface with a respective port of the first vacuum transfer module; and/or (f) the buffer station includes alignment pins configured to align a first port of the second vacuum transfer module interface with a respective port of the second vacuum transfer module.
The buffer station, as described in the previous buffer station description, includes these features: (a) It connects to an inert gas supply to improve heat transfer between the pedestal and the wafer. (b) It connects to a vacuum pump to control pressure inside the buffer chamber. (c) The first vacuum transfer interface uses a slit valve to isolate the buffer chamber from the first vacuum transfer module's vacuum environment. (d) The second vacuum transfer interface uses a slit valve to isolate the buffer chamber from the second vacuum transfer module's vacuum environment. (e/f) Alignment pins ensure proper alignment between the buffer station interfaces and the vacuum transfer modules.
6. The buffer station of claim 1 , wherein the lower pedestal includes: (a) at least one outlet in the support surface which delivers a heat transfer gas to an underside of a semiconductor substrate supported thereon, and at least one gas passage extending through the lower pedestal connected to a source of heat transfer gas operable to supply heat transfer gas at a desired pressure to the at least one gas passage; (b) a monopolar or bipoloar electrostatic clamping electrode operable to apply an electrostatic clamping force to a semiconductor substrate on the support surface when an electrostatic clamping voltage is applied to the monopolar or bipolar electrostatic clamping electrode; and/or (c) lift pins operable to lower a semiconductor substrate onto the support surface of the lower pedestal and to raise the semiconductor substrate from the support surface of the lower pedestal.
The lower pedestal in the buffer station, as described in the previous buffer station description, includes one or more of the following features: (a) It has outlets in its support surface that deliver a heat transfer gas to the wafer's underside. Gas passages within the pedestal connect these outlets to a gas supply at a controlled pressure. (b) It has a monopolar or bipolar electrostatic clamping electrode that applies force to hold the wafer in place when a voltage is applied. (c) It includes lift pins to raise and lower the wafer onto and off of the support surface.
7. A modular semiconductor substrate processing system including a buffer station for thermal control of semiconductor substrates being transferred therethrough, the modular semiconductor substrate processing system comprising: a first vacuum transfer module; a second vacuum transfer module; and a buffer station interfaced with the first vacuum transfer module and the second vacuum transfer module so as to allow semiconductor substrates to be transferred therebetween, the buffer station comprising: a first vacuum transfer module interface operable to allow one or more semiconductor substrates to be transferred between the first vacuum transfer module and the buffer station at vacuum pressure; a second vacuum transfer module interface operable to allow one or more semiconductor substrates to be transferred between the second vacuum transfer module and the buffer station at vacuum pressure; and at least one buffer chamber between the first vacuum transfer module interface and the second vacuum transfer module interface, each of the at least one buffer chambers including a lower pedestal that forms a bottom most interior surface of the buffer chamber, that is operable to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module on a support surface thereof, and that is operable to perform a heating or cooling operation on the semiconductor substrate received thereon, and one or more semiconductor substrate storage shelves that are located above the lower pedestal, that extend outwardly from a side wall of the buffer chamber, and that are each operable to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module wherein each semiconductor substrate storage shelf is operable to store a respective semiconductor substrate thereon.
A modular semiconductor processing system has first and second vacuum transfer modules connected by a buffer station. The buffer station includes two vacuum interfaces for transferring wafers to/from the modules. A buffer chamber between the interfaces has a lower pedestal to hold a wafer, with heating/cooling capability to thermally control the wafer. One or more storage shelves are located above the pedestal to store wafers temporarily. This enables wafers to be staged, and their temperatures controlled, between processing steps performed by modules connected to the vacuum transfer modules.
8. The modular semiconductor substrate processing system of claim 7 , wherein the lower pedestal includes a heater layer which includes independently controllable heater zones operable to independently control and tune the spatial and temporal temperature of the support surface of the lower pedestal; and/or the lower pedestal includes a cooling layer operable to reduce the temperature of the lower pedestal.
The modular semiconductor substrate processing system that uses a buffer station, as described in the previous description, has the lower pedestal which includes a heater layer with independently controllable heater zones, allowing precise spatial and temporal temperature control of the wafer support surface. Alternatively, or in addition, the lower pedestal includes a cooling layer to reduce the pedestal's temperature, enabling cooling of the wafer.
9. The modular semiconductor substrate processing system of claim 7 , wherein the at least one buffer chamber includes a heat shield between the lower pedestal and the one or more semiconductor substrate storage shelves wherein the heat shield is operable to reduce heat transfer between a semiconductor substrate supported on the lower pedestal and one or more substrates supported on the respective one or more semiconductor substrate storage shelves during processing.
The modular semiconductor substrate processing system that uses a buffer station, as described in the previous description, has the buffer chamber which includes a heat shield positioned between the lower pedestal and the storage shelves. This heat shield reduces heat transfer between a wafer on the pedestal (being heated or cooled) and wafers stored on the shelves, preventing unwanted temperature changes to the stored wafers during processing.
10. The modular semiconductor substrate processing system of claim 7 , wherein: (a) the at least one buffer chamber includes a first buffer chamber disposed above a second buffer chamber wherein the first buffer chamber is operable to allow semiconductor substrates to be transferred from the first vacuum transfer module to the second vacuum transfer module and the second buffer chamber is operable to allow semiconductor substrates to be transferred from the second vacuum transfer module to the first vacuum transfer module; or (b) the at least one buffer chamber includes a first buffer chamber disposed above a second buffer chamber wherein the first buffer chamber is operable to allow semiconductor substrates to be transferred from the first vacuum transfer module to the second vacuum transfer module and the second buffer chamber is operable to allow semiconductor substrates to be transferred from the second vacuum transfer module to the first vacuum transfer module wherein the buffer station includes a driver operable to lower the first and second buffer chambers so as to allow semiconductor substrates to be transferred through the first buffer chamber and to raise the first and second buffer chambers so as to allow semiconductor substrates to be transferred through the second buffer chamber.
The modular semiconductor substrate processing system that uses a buffer station, as described in the previous description, can have multiple buffer chambers arranged vertically. In one configuration, a first buffer chamber is positioned above a second. The first chamber facilitates wafer transfer from the first vacuum transfer module to the second, and the second chamber allows transfer from the second vacuum transfer module back to the first. Alternatively, the buffer station uses a driver to lower/raise the buffer chambers so that wafer can be transferred back and forth.
11. The modular semiconductor substrate processing system of claim 7 , wherein: (a) the buffer station is in fluid communication with an inert gas supply, the inert gas supply operable to supply inert gas to the at least one buffer chamber so as to facilitate heat transfer between the lower pedestal and a semiconductor substrate supported on the lower pedestal; (b) the buffer station is in fluid communication with a vacuum pump, the vacuum pump operable to control the pressure within the at least one buffer chamber; (c) the first vacuum transfer module interface includes a first slit valve operable to seal a first port of the first vacuum transfer module interface, the first slit valve operable to isolate the environment of the at least one buffer chamber from a vacuum environment of the first vacuum transfer module; (d) the second vacuum transfer module interface includes a second slit valve operable to seal a first port of the second vacuum transfer module interface, the second slit valve operable to isolate the environment of the at least one buffer chamber from a vacuum environment of the second vacuum transfer module; (d) the buffer station includes alignment pins operable to align a first port of the first vacuum transfer module interface with a respective port of the first vacuum transfer module; (e) the buffer station includes alignment pins operable to align a first port of the second vacuum transfer module interface with a respective port of the second vacuum transfer module; (f) the modular semiconductor substrate processing system further comprises a controller configured to control processes performed by the system; and/or (g) the modular semiconductor substrate processing system further comprises a non-transitory computer machine-readable medium comprising program instructions for control of the system.
The modular semiconductor substrate processing system that uses a buffer station, as described in the previous description, includes these features: (a) The buffer station connects to an inert gas supply to improve heat transfer between the pedestal and the wafer. (b) The buffer station connects to a vacuum pump to control pressure inside the buffer chamber. (c) The first vacuum transfer interface uses a slit valve to isolate the buffer chamber from the first vacuum transfer module's vacuum environment. (d) The second vacuum transfer interface uses a slit valve to isolate the buffer chamber from the second vacuum transfer module's vacuum environment. (e/f) Alignment pins ensure proper alignment between the buffer station interfaces and the vacuum transfer modules. (g) It includes a controller and software.
12. The modular semiconductor substrate processing system of claim 7 , wherein the lower pedestal includes: (a) at least one outlet in the support surface which delivers a heat transfer gas to an underside of a semiconductor substrate supported thereon, and at least one gas passage extending through the lower pedestal connected to a source of heat transfer gas operable to supply heat transfer gas at a desired pressure to the at least one gas passage; (b) a monopolar or bipoloar electrostatic clamping electrode operable to apply an electrostatic clamping force to a semiconductor substrate on the support surface when an electrostatic clamping voltage is applied to the monopolar or bipolar electrostatic clamping electrode; and/or (c) lift pins operable to lower a semiconductor substrate onto the support surface of the lower pedestal and to raise the semiconductor substrate from the support surface of the lower pedestal.
The modular semiconductor substrate processing system that uses a buffer station, as described in the previous description, has the lower pedestal which includes one or more of the following features: (a) It has outlets in its support surface that deliver a heat transfer gas to the wafer's underside. Gas passages within the pedestal connect these outlets to a gas supply at a controlled pressure. (b) It has a monopolar or bipolar electrostatic clamping electrode that applies force to hold the wafer in place when a voltage is applied. (c) It includes lift pins to raise and lower the wafer onto and off of the support surface.
13. The modular semiconductor substrate processing system of claim 7 , wherein (a) the first vacuum transfer module is in operational relationship with an equipment front end module (EFEM), the EFEM operable to receive semiconductor substrates at atmospheric pressure from a front opening unified pod (FOUP) and transfer the semiconductor substrates to a vacuum environment of the first vacuum transfer module; (b) the first vacuum transfer module is in operational relationship with one or more semiconductor substrate processing modules operable to perform one or more processing operations on a semiconductor substrate; (c) the second vacuum transfer module is in operational relationship with one or more semiconductor substrate processing modules operable to perform one or more processing operations on a semiconductor substrate; (d) the first vacuum transfer module includes a robot in a vacuum environment thereof operable to transfer semiconductor substrates through the first vacuum transfer module interface; and/or (e) the second vacuum transfer module includes a robot in a vacuum environment thereof operable to transfer semiconductor substrates through the second vacuum transfer module interface.
In the modular semiconductor substrate processing system, using a buffer station as described in claim 7, (a) the first vacuum transfer module is connected to an EFEM which receives wafers at atmospheric pressure from a FOUP and transfers them into a vacuum. (b/c) The first and second vacuum transfer modules are connected to processing modules. (d/e) The first and second vacuum transfer modules each have a robot that transfers wafers through the vacuum transfer interface.
14. The modular semiconductor substrate processing system of claim 7 , wherein: (a) the buffer station is supported by a frame of the first or second vacuum transfer modules; or (b) the buffer station is suspended between the first and second vacuum transfer modules.
The modular semiconductor substrate processing system that uses a buffer station, as described in claim 7, the buffer station is either (a) supported by a frame of the vacuum transfer modules, or (b) suspended between the vacuum transfer modules.
15. A modular semiconductor substrate processing system comprising three or more vacuum transfer modules, each vacuum transfer module in operational relationship with at least one other vacuum transfer module by the buffer station of claim 1 .
A modular semiconductor substrate processing system has three or more vacuum transfer modules. Each vacuum transfer module is connected to at least one other vacuum transfer module using the buffer station described previously in claim 1.
16. The modular semiconductor substrate processing system of claim 15 , wherein: (a) at least one of the vacuum transfer modules is in operational relationship with an EFEM operable to receive semiconductor substrates at atmospheric pressure from a front opening unified pod (FOUP) and transfer the semiconductor substrates to a vacuum environment thereof; and/or (b) each vacuum transfer module is in operational relationship with one or more semiconductor substrate processing modules operable to perform one or more processing operations on a semiconductor substrate.
In the modular semiconductor substrate processing system using three or more vacuum transfer modules that are each connected to at least one other vacuum transfer module using the buffer station described previously in claim 1, (a) At least one vacuum transfer module is connected to an EFEM, which receives wafers at atmospheric pressure from a FOUP and transfers them into a vacuum. (b) Each vacuum transfer module is connected to one or more processing modules.
17. A method of transferring semiconductor substrates through a buffer station between a first vacuum transfer module and a second vacuum transfer module of a modular semiconductor substrate processing system, the method comprising: transferring a semiconductor substrate from a first vacuum transfer module through a first vacuum transfer module interface into a first buffer chamber of the buffer station; supporting the semiconductor substrate on a support surface of a lower pedestal disposed in the first buffer chamber and forming a bottom most interior surface of the buffer chamber; performing a heating or cooling operation on the semiconductor substrate supported on the support surface of the lower pedestal; and transferring the semiconductor substrate from the lower pedestal of the first buffer chamber through a second vacuum transfer module interface of the buffer station to a second vacuum transfer module; and storing the semiconductor substrate on a semiconductor substrate storage shelf in the first buffer chamber before the semiconductor substrate is supported on the support surface of the lower pedestal of the buffer chamber, the semiconductor storage shelf being located above the lower pedestal and extending outwardly from a side wall of the first buffer chamber.
A method for transferring wafers between two vacuum transfer modules using a buffer station: A wafer is transferred from a first vacuum transfer module into a buffer chamber. The wafer is placed on a lower pedestal in the chamber, and then the wafer is heated or cooled. The wafer is then transferred from the buffer chamber to a second vacuum transfer module. The method also includes storing the wafer on a shelf located above the pedestal before it is placed on the pedestal.
18. The method of claim 17 , and (a) increasing the pressure in the first buffer chamber during the heating or cooling operation so as to increase heat transfer between the support surface of the lower pedestal and the semiconductor substrate; (b) providing an inert gas environment in the first buffer chamber during the heating or cooling operation; (c)isolating the first buffer chamber environment from the first and/or second vacuum transfer modules during the heating or cooling operation; (d) delivering a heat transfer gas to an underside of the semiconductor substrate supported on the support surface during the heating or cooling operation; (e) electrostatically clamping the semiconductor substrate to the support surface of the lower pedestal during the heating or cooling operation; and/or (f) independently controlling and tuning the spatial and temporal temperature of the support surface of the lower pedestal with a heater layer including independently controllable heater zones during the heating or cooling operation.
The wafer transfer method using the buffer station, as described in the previous method description, includes one or more of the following steps: (a) Increasing the pressure in the buffer chamber during heating/cooling to improve heat transfer. (b) Providing an inert gas environment during heating/cooling. (c) Isolating the buffer chamber from the vacuum transfer modules during heating/cooling. (d) Delivering a heat transfer gas to the wafer's underside during heating/cooling. (e) Electrostatically clamping the wafer to the pedestal during heating/cooling. (f) Independently controlling and tuning the spatial and temporal temperature of the support surface of the lower pedestal with a heater layer including independently controllable heater zones during the heating or cooling operation.
19. The method of claim 17 , further comprising: transferring the semiconductor substrate from the second vacuum chamber through the second vacuum transfer module interface into the first buffer chamber of the buffer station; and supporting the semiconductor substrate on the support surface of the lower pedestal disposed in the first buffer chamber and performing one of: a heating or cooling operation on the semiconductor substrate supported on the support surface of the lower pedestal; and storing the semiconductor substrate on a second semiconductor substrate storage shelf in the first buffer chamber; and transferring the semiconductor substrate from the first buffer chamber through the first vacuum transfer module interface of the buffer station to the first vacuum transfer module.
The wafer transfer method using the buffer station, as described in claim 17, further comprises transferring a wafer from the second vacuum chamber through the second vacuum transfer module interface into the first buffer chamber of the buffer station. The wafer is placed on a lower pedestal in the chamber where the wafer is heated or cooled. The wafer is stored on a shelf and then transferred to the first vacuum transfer module.
20. The method of claim 17 , further comprising; transferring the semiconductor substrate from the second vacuum chamber through the second vacuum transfer module interface into a second buffer chamber of the buffer station; supporting the semiconductor substrate on a support surface of a lower pedestal disposed in the second buffer chamber and performing one of: a heating or cooling operation on the semiconductor substrate supported on the support surface of the lower pedestal; and storing the semiconductor substrate on a second semiconductor substrate storage shelf in the second buffer chamber; and transferring the semiconductor substrate from the second buffer chamber through the first vacuum transfer module interface of the buffer station to the first vacuum transfer module.
The wafer transfer method using the buffer station, as described in claim 17, further comprises transferring a wafer from the second vacuum chamber through the second vacuum transfer module interface into a second buffer chamber of the buffer station. The wafer is placed on a lower pedestal in the chamber where the wafer is heated or cooled. The wafer is stored on a shelf and then transferred from the second buffer chamber through the first vacuum transfer module interface of the buffer station to the first vacuum transfer module.
21. A buffer station for thermal control of semiconductor substrates in a modular semiconductor substrate processing system being transferred therethrough, the buffer station configured to interface with first and second vacuum transfer modules of the modular semiconductor substrate processing system so as to allow semiconductor substrates to be transferred therebetween, the buffer station comprising: a first vacuum transfer module interface configured to allow one or more semiconductor substrates to be transferred between the first vacuum transfer module and the buffer station at vacuum pressure; a second vacuum transfer module interface configured to allow one or more semiconductor substrates to be transferred between the second vacuum transfer module and the buffer station at vacuum pressure; and at least one buffer chamber between the first vacuum transfer module interface and the second vacuum transfer module interface, the at least one buffer chamber including a lower pedestal configured to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module on a support surface thereof and operable to perform a heating or cooling operation on the semiconductor substrate received thereon, and one or more semiconductor substrate storage shelves above the lower pedestal which are each configured to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module wherein each semiconductor substrate storage shelf is operable to store a respective semiconductor substrate thereon wherein at least one of: (a) the buffer station is configured to be in fluid communication with an inert gas supply, the inert gas supply operable to supply inert gas to the at least one buffer chamber so as to facilitate heat transfer between the lower pedestal and a semiconductor substrate supported on the lower pedestal; (b) the buffer station is configured to be in fluid communication with a vacuum pump, the vacuum pump operable to control the pressure within the at least one buffer chamber; (c) the first vacuum transfer module interface includes a first slit valve operable to seal a first port of the first vacuum transfer module interface, the first slit valve configured to isolate the environment of the at least one buffer chamber from a vacuum environment of the first vacuum transfer module; (d) the second vacuum transfer module interface includes a second slit valve operable to seal a first port of the second vacuum transfer module interface, the second slit valve configured to isolate the environment of the at least one buffer chamber from a vacuum environment of the second vacuum transfer module; (e) the buffer station includes alignment pins configured to align a first port of the first vacuum transfer module interface with a respective port of the first vacuum transfer module; and (f) the buffer station includes alignment pins configured to align a first port of the second vacuum transfer module interface with a respective port of the second vacuum transfer module.
A buffer station for semiconductor wafers being transferred, interfacing with first and second vacuum transfer modules, and having interfaces to each module for wafer transfer under vacuum. The buffer chamber includes a lower pedestal for heating/cooling, and storage shelves for storing wafers. The buffer station also includes one or more of: (a) An inert gas supply for heat transfer enhancement; (b) A vacuum pump for pressure control; (c) A first slit valve to isolate the first module; (d) A second slit valve to isolate the second module; (e/f) Alignment pins for aligning to the vacuum transfer modules.
22. A buffer station for thermal control of semiconductor substrates in a modular semiconductor substrate processing system being transferred therethrough, the buffer station configured to interface with first and second vacuum transfer modules of the modular semiconductor substrate processing system so as to allow semiconductor substrates to be transferred therebetween, the buffer station comprising: a first vacuum transfer module interface configured to allow one or more semiconductor substrates to be transferred between the first vacuum transfer module and the buffer station at vacuum pressure; a second vacuum transfer module interface configured to allow one or more semiconductor substrates to be transferred between the second vacuum transfer module and the buffer station at vacuum pressure; and at least one buffer chamber between the first vacuum transfer module interface and the second vacuum transfer module interface, the at least one buffer chamber including a lower pedestal configured to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module on a support surface thereof and operable to perform a heating or cooling operation on the semiconductor substrate received thereon, and one or more semiconductor substrate storage shelves above the lower pedestal which are each configured to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module wherein each semiconductor substrate storage shelf is operable to store a respective semiconductor substrate thereon, wherein the lower pedestal includes at least one of: (a) at least one outlet in the support surface which delivers a heat transfer gas to an underside of a semiconductor substrate supported thereon, and at least one gas passage extending through the lower pedestal connected to a source of heat transfer gas operable to supply heat transfer gas at a desired pressure to the at least one gas passage; (b) a monopolar or bipoloar electrostatic clamping electrode operable to apply an electrostatic clamping force to a semiconductor substrate on the support surface when an electrostatic clamping voltage is applied to the monopolar or bipolar electrostatic clamping electrode; and (c) lift pins operable to lower a semiconductor substrate onto the support surface of the lower pedestal and to raise the semiconductor substrate from the support surface of the lower pedestal.
A buffer station for semiconductor wafers being transferred, interfacing with first and second vacuum transfer modules, and having interfaces to each module for wafer transfer under vacuum. The buffer chamber includes a lower pedestal for heating/cooling, and storage shelves for storing wafers. The lower pedestal has at least one of: (a) Outlets for heat transfer gas to the wafer underside and passages for gas supply; (b) An electrostatic clamp; (c) Lift pins for loading and unloading wafers.
23. A modular semiconductor substrate processing system including a buffer station for thermal control of semiconductor substrates being transferred therethrough, the modular semiconductor substrate processing system comprising: a first vacuum transfer module; a second vacuum transfer module; and a buffer station interfaced with the first vacuum transfer module and the second vacuum transfer module so as to allow semiconductor substrates to be transferred therebetween, the buffer station comprising: a first vacuum transfer module interface operable to allow one or more semiconductor substrates to be transferred between the first vacuum transfer module and the buffer station at vacuum pressure; a second vacuum transfer module interface operable to allow one or more semiconductor substrates to be transferred between the second vacuum transfer module and the buffer station at vacuum pressure; and at least one buffer chamber between the first vacuum transfer module interface and the second vacuum transfer module interface, the at least one buffer chamber including a lower pedestal operable to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module on a support surface thereof and operable to perform a heating or cooling operation on the semiconductor substrate received thereon, and one or more semiconductor substrate storage shelves above the lower pedestal which are each operable to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module wherein each semiconductor substrate storage shelf is operable to store a respective semiconductor substrate thereon, wherein at least one of: (a) the buffer station is in fluid communication with an inert gas supply, the inert gas supply operable to supply inert gas to the at least one buffer chamber so as to facilitate heat transfer between the lower pedestal and a semiconductor substrate supported on the lower pedestal; (b) the buffer station is in fluid communication with a vacuum pump, the vacuum pump operable to control the pressure within the at least one buffer chamber; (c) the first vacuum transfer module interface includes a first slit valve operable to seal a first port of the first vacuum transfer module interface, the first slit valve operable to isolate the environment of the at least one buffer chamber from a vacuum environment of the first vacuum transfer module; (d) the second vacuum transfer module interface includes a second slit valve operable to seal a first port of the second vacuum transfer module interface, the second slit valve operable to isolate the environment of the at least one buffer chamber from a vacuum environment of the second vacuum transfer module; (d) the buffer station includes alignment pins operable to align a first port of the first vacuum transfer module interface with a respective port of the first vacuum transfer module; (e) the buffer station includes alignment pins operable to align a first port of the second vacuum transfer module interface with a respective port of the second vacuum transfer module; (f) modular semiconductor substrate processing system includes a controller configured to control processes performed by the system; and (g) modular semiconductor substrate processing system includes a non-transitory computer machine-readable medium comprising program instructions for control of the system.
A modular semiconductor substrate processing system including a first vacuum transfer module, a second vacuum transfer module, and a buffer station interfaced with the modules. The buffer station includes vacuum interfaces and a buffer chamber with a lower pedestal for heating/cooling, and storage shelves. The system includes one or more of: (a) An inert gas supply for heat transfer enhancement; (b) A vacuum pump for pressure control; (c) A first slit valve to isolate the first module; (d) A second slit valve to isolate the second module; (e/f) Alignment pins for aligning to the vacuum transfer modules; (g) A controller; and (h) Non-transitory computer readable medium and code for control.
24. A modular semiconductor substrate processing system including a buffer station for thermal control of semiconductor substrates being transferred therethrough, the modular semiconductor substrate processing system comprising: a first vacuum transfer module; a second vacuum transfer module; and a buffer station interfaced with the first vacuum transfer module and the second vacuum transfer module so as to allow semiconductor substrates to be transferred therebetween, the buffer station comprising: a first vacuum transfer module interface operable to allow one or more semiconductor substrates to be transferred between the first vacuum transfer module and the buffer station at vacuum pressure; a second vacuum transfer module interface operable to allow one or more semiconductor substrates to be transferred between the second vacuum transfer module and the buffer station at vacuum pressure; and at least one buffer chamber between the first vacuum transfer module interface and the second vacuum transfer module interface, the at least one buffer chamber including a lower pedestal operable to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module on a support surface thereof and operable to perform a heating or cooling operation on the semiconductor substrate received thereon, and one or more semiconductor substrate storage shelves above the lower pedestal which are each operable to receive a semiconductor substrate from the first vacuum transfer module or the second vacuum transfer module wherein each semiconductor substrate storage shelf is operable to store a respective semiconductor substrate thereon, wherein the lower pedestal includes at least one of: (a) at least one outlet in the support surface which delivers a heat transfer gas to an underside of a semiconductor substrate supported thereon, and at least one gas passage extending through the lower pedestal connected to a source of heat transfer gas operable to supply heat transfer gas at a desired pressure to the at least one gas passage; (b) a monopolar or bipoloar electrostatic clamping electrode operable to apply an electrostatic clamping force to a semiconductor substrate on the support surface when an electrostatic clamping voltage is applied to the monopolar or bipolar electrostatic clamping electrode; and (c) lift pins operable to lower a semiconductor substrate onto the support surface of the lower pedestal and to raise the semiconductor substrate from the support surface of the lower pedestal.
A modular semiconductor substrate processing system including a first vacuum transfer module, a second vacuum transfer module, and a buffer station interfaced with the modules. The buffer station includes vacuum interfaces and a buffer chamber with a lower pedestal for heating/cooling, and storage shelves. The lower pedestal has at least one of: (a) Outlets for heat transfer gas to the wafer underside and passages for gas supply; (b) An electrostatic clamp; (c) Lift pins for loading and unloading wafers.
25. A method of transferring semiconductor substrates through a buffer station between a first vacuum transfer module and a second vacuum transfer module of a modular semiconductor substrate processing system, the method comprising: transferring a semiconductor substrate from a first vacuum transfer module through a first vacuum transfer module interface into a first buffer chamber of the buffer station; supporting the semiconductor substrate on a support surface of a lower pedestal disposed in the first buffer chamber; performing a heating or cooling operation on the semiconductor substrate supported on the support surface of the lower pedestal; transferring the semiconductor substrate from the lower pedestal of the first buffer chamber through a second vacuum transfer module interface of the buffer station to a second vacuum transfer module; and at least one of: (a) storing the semiconductor substrate on a semiconductor substrate storage shelf in the first buffer chamber before the semiconductor substrate is supported on the support surface of the lower pedestal of the buffer chamber; (b) increasing the pressure in the first buffer chamber during the heating or cooling operation so as to increase heat transfer between the support surface of the lower pedestal and the semiconductor substrate; (c) providing an inert gas environment in the first buffer chamber during the heating or cooling operation; (d) isolating the first buffer chamber environment from the first and/or second vacuum transfer modules during the heating or cooling operation; (e) delivering a heat transfer gas to an underside of the semiconductor substrate supported on the support surface during the heating or cooling operation; (f) electrostatically clamping the semiconductor substrate to the support surface of the lower pedestal during the heating or cooling operation; and (g) independently controlling and tuning the spatial and temporal temperature of the support surface of the lower pedestal with a heater layer including independently controllable heater zones during the heating or cooling operation.
A method of transferring semiconductor substrates through a buffer station between a first vacuum transfer module and a second vacuum transfer module. The method involves transferring the wafer from the first vacuum transfer module, supporting it on a pedestal, performing heating or cooling, then transferring to the second vacuum transfer module. The method includes one or more of the following: (a) storing the substrate on a shelf; (b) increasing buffer chamber pressure; (c) inert gas environment; (d) isolating the chamber; (e) delivering heat transfer gas to the underside; (f) electrostatic clamping; (g) independently controlling and tuning the spatial and temporal temperature of the support surface of the lower pedestal with a heater layer including independently controllable heater zones during the heating or cooling operation.
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October 23, 2014
June 6, 2017
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